Validating the Cognitive Network Controller on NASA’s SCaN Testbed

ICC 2020 - 2020 IEEE International Conference on Communications (ICC) Pub Date : 2020-06-01 DOI:10.1109/ICC40277.2020.9149160

R. Lent, D. Brooks, G. Clark

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引用次数: 6

Abstract

The Cognitive Network Controller (CNC) defines a neuromorphic architecture where a spiking neural network can both encode network performance observations and select the optimal actions (e.g., routes) for the context of those observations. Because of these features, the CNC can quickly adapt to changes in the operational environment to either maintain or improve selected performance metrics. This behavior can be attractive for a space networking scenario with orbiting and ground-based assets that are either stationary or manned, bringing an elevated level of autonomy in network communication decisions. Using the SCaN testbed as a laboratory facility in orbit, we evaluated the adaptation abilities of the CNC applied to a space network routing application. Towards this end, the CNC design and the related neuromorphic processor were implemented in software and deployed on the flight computer of the SCaN testbed, and then applied to route bundles to a ground station over parallel links. This work likely constitutes the earliest demonstration of a space application for neuromorphic computing and a basic validation of the online adaptation capabilities of the CNC.

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在NASA扫描测试台上验证认知网络控制器

认知网络控制器(CNC)定义了一种神经形态架构，其中一个峰值神经网络可以对网络性能观察进行编码，并为这些观察的上下文选择最佳行为(例如，路由)。由于这些特性，CNC可以快速适应操作环境的变化，以保持或改进选定的性能指标。这种行为对于轨道和地面固定或载人资产的空间网络场景具有吸引力，从而提高了网络通信决策的自主性。利用SCaN试验台作为轨道上的实验室设施，我们评估了CNC在空间网络路由应用中的适应能力。为此，CNC设计和相关的神经形态处理器在软件中实现，并部署在SCaN试验台的飞行计算机上，然后应用于通过平行链路到地面站的路由束。这项工作可能是神经形态计算空间应用的最早演示，也是CNC在线适应能力的基本验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ICC 2020 - 2020 IEEE International Conference on Communications (ICC)

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